Back to EveryPatent.com
United States Patent |
5,237,848
|
Campbell
|
August 24, 1993
|
Method and apparatus for expanding and contouring honeycomb core
Abstract
A method and apparatus for expanding and contouring honeycomb preforms into
compound curved honeycomb core sheets. Honeycomb preforms are provided
having a plurality of face to face, contiguous, strips bonded together at
selected narrow areas such that when strips along opposite edges are moved
away from each other a sheet having a repeating array of regular hexagonal
cells results. Opposite edge strips are secured to two spaced arms located
adjacent to a freely rotatable crowned drum having a surface contour
corresponding to the desired honeycomb sheet configuration. One of said
arms is pivoted about the drum axis. As the arms are moved apart, a flat
partially expanded honeycomb sheet initially develops. As arm movement
continues, the sheet then comes into sliding contact with the drum
surface. When cell expansion is completed, during the final shaping and
setting phase, the honeycomb core sheet is in full contact with the drum
surface. The resulting compound curved sheet is removed, trimmed and is
ready for further processing, such as bonding face sheets thereto. Very
uniform hexagonal cells result with no significant distortion.
Non-compound, generally cylindrical expanded honeycomb sheets may be
formed by utilizing only a slight drum crown.
Inventors:
|
Campbell; Kenneth L. (Yucaipa, CA)
|
Assignee:
|
Rohr, Inc. (Chula Vista, CA)
|
Appl. No.:
|
812031 |
Filed:
|
December 23, 1991 |
Current U.S. Class: |
72/296; 29/6.1; 72/151; 72/183; 72/303; 72/406; 428/116; 428/542.8 |
Intern'l Class: |
B21D 031/04; B21D 011/02 |
Field of Search: |
72/302,303,297,296,151,406,149,183,199
29/6.1,6.2
|
References Cited
U.S. Patent Documents
974288 | Nov., 1910 | McCarroll | 72/406.
|
1910832 | May., 1933 | Henderson | 72/406.
|
2633893 | Apr., 1953 | Philippi | 72/183.
|
3478553 | Nov., 1969 | Weglarz | 72/296.
|
3545242 | Dec., 1970 | Dean | 72/151.
|
3879994 | Apr., 1975 | Hume | 72/406.
|
4187711 | Feb., 1980 | Lavochkin | 72/303.
|
4893391 | Jan., 1990 | Zobel | 72/296.
|
Primary Examiner: Crane; Daniel C.
Attorney, Agent or Firm: Schlesinger; Patrick J., Gilliam; Frank D.
Claims
I claim:
1. Apparatus for expanding and contouring honeycomb preforms into compound
curved honeycomb sheets which comprises:
a supporting structure;
a drum having a crowned surface;
said drum mounted on said supporting structure for free rotation about its
axis;
a first arm assembly mounted on said supporting structure adjacent to said
drum surface;
first connecting means on said arm assembly adapted to engage and hold
outside end strips of a honeycomb preform;
a second, movable, arm assembly mounted on said supporting structure for
pivoting movement about said drum axis relative to said free rotation of
said drum;
second connection means on said second arm assembly adapted to engage and
hold the second, opposite, end strips of said honeycomb preform;
means for rotating said second arm assembly away from said first arm to
cause said honeycomb preform to initially expand in a generally flat
configuration; and
said arm assemblies and drum being relatively positioned so that said
expanding preform will come into sliding contact with said crowned surface
as said surface freely rotates with said preform, after a selected degree
of initial expansion;
whereby a full expansion of said preform is achieved a fully expanded and
shaped honeycomb sheet corresponding to said crowned surface results.
2. The apparatus according to claim 1 wherein said first arm assembly
comprises:
a pair of fixed brackets located adjacent to the edges of said drum
surface;
a first bar extending between said brackets substantially parallel to the
drum axis; and
a plurality of spaced connection means along said first bar each adapted to
connect to said first outside strip of said preform.
3. The apparatus according to claim 2 wherein said connection means
comprises a plurality of spaced filaments that are threaded between
preform strips near the edge thereof and around said first bar to flexibly
secure said preform to said bar.
4. The apparatus according to claim 1 wherein said second arm assembly
comprises:
a pair of elongated plates substantially parallel to the drum ends;
drum axis bearing means at first end of each of said plates to allow said
plates to pivot about said drum axis relative to said free rotation of
said drum;
the second plates ends extending beyond the drum surface and includes means
for removably holding a second bar;
said second bar extending across the drum surface between said second plate
ends and spaced a selected distance from the drum surface; and
a plurality of spaced connections means along said bar, each adapted to
connect to said outside strip of a honeycomb preform.
5. The apparatus according to claim 4 wherein said connection means
comprises a plurality of spaced filaments that are threaded between
preform strips near the edge thereof and around said second bar to
flexibly secure said preform to said bar.
6. The apparatus according to claim 1 wherein said arms are positioned
relative to said drum surface such that said expanding preform will come
into initial contact with said drum surface after about 50 to 80% of full
expansion has occurred.
7. The apparatus according to claim 1 wherein said crowned surface is a
surface of revolution.
8. The apparatus according to claim 1 wherein the surface material of said
drum is selected from the group consisting of metal and fiber reinforced
organic matrix composites.
9. The apparatus according to claim 1 wherein said expanding preform comes
into contact with said crowned surface less than about 30% of the
circumference of the drum.
10. The method of expanding and contouring honeycomb preforms into compound
curved honeycomb sheets which comprise:
providing a honeycomb preform comprising a plurality of contiguous strips
bonded together in selected areas whereby a honeycomb sheet can be formed
by moving outside strips away form each other;
securing the outside strips along a first edge of said preform to a first
arm assembly;
securing the outside strips along the second edge of said preform to a
second arm assembly;
moving at least one of said arm assemblies away from the other to expand
said preform to a selected fraction of the full expansion necessary to
provide hexagonal cells;
bringing the resulting partially expanded preform into sliding contact with
a freely rotatable crowned forming surface; and
continuing movement of at least one arm assembly away from the other to
expand said preform to said full expansion while gradually increasing the
area of contact between said preform and said forming surface the
expansion of said preform during said movement of said at least one arm
assembly causing said freely rotatable crown surface to slide;
whereby a compound curved honeycomb sheet is produced with substantially no
damage to honeycomb cells.
11. The method according to claim 10 including fixedly positioning one of
said arms adjacent to said freely rotatable crowned forming surface and
pivotably mounting the second arm on a shaft about which said freely
rotatable crowned forming surface rotates and said second arm is moved
away from said first arm by pivoting said second arm about said shaft.
12. The method according to claim 10 wherein said preform is secured to
each of said arm assemblies by threading a plurality of wires through said
preform between strips along each edge and around a bar fastened to each
adjacent arm assembly.
13. The method according to claim 10 including positioning said arms
relative to said drum surface such that said expanding preform will come
into contact with said drum surface after about 50 to 80% of full
honeycomb expansion has occurred.
14. The method according to claim 10 wherein said expanding preform comes
into full contact with the drum surface after from about 79 to 90% of full
expansion and remaining expansion .is accomplished with the preform in
full contact with the drum surface.
15. The method according to claim 10 wherein said expanding preform comes
in contact with said drum surface less than about 30% of the circumference
of the drum.
Description
BACKGROUND OF THE INVENTION
This invention relates in general to the production of expanded metal
honeycomb sheet material and, more specifically, to a method and apparatus
for expanding and forming contoured metal honeycomb sheets.
Honeycomb core panels have come into widespread use in a variety of
applications that require a combination of high strength and light weight.
Honeycomb sheets are formed from preforms that basically consist of a
large number of narrow strips of metal material, such as aluminum, stacked
and bonded together in small spaced areas, such as by adhesive or solder
bonding, so that when the outside edge strips are pulled away from each
other the preform expands into a sheet having a uniform pattern of a very
large number of small hexagonal cells, resembling a honeycomb. Typical of
the prior art methods of producing honeycomb core preforms is that
described by Hartsell in U.S. Pat. No. 3,077,223. This core is
conventionally formed into flat panels by stretching strips on opposite
sides away from each other, as described by Steele et al in U.S. Pat. No.
2,674,295.
When face sheets, such as thin aluminum sheets, are bonded to the faces of
the honeycomb core, a panel with a very high strength to weight ratio
results.
These honeycomb core panels are widely used in flat or cylindrical shapes
for a variety of purposes. In some cases, complex curved shapes are
required. For example, in aircraft engine casings or nacelles, fuselage
panels, and other aerospace applications shapes, such as simple curves and
compound curves, which are basically crowned cylindrical shapes are often
required.
In the past, such shapes have generally been formed by pulling a honeycomb
preform into an expanded flat sheet or plank. The fully expanded sheet is
then roll formed by passing the sheet through a series of forming rollers.
Typical of this system is that disclosed by Curran in U.S. Pat. No.
4,054,477. This method is generally suitable only for contouring the sheet
in one direction. Unfortunately, this method often mutilates or distorts
cells and areas of the sheet surface, so that generally only about 50% of
the shaped honeycomb sheets are acceptable for use. Attempts to roll form
in two directions generally result in unacceptable cell damage. Curved
honeycomb core can also be formed by stretch forming the honeycomb core or
on a fixed cylindrical curved surface as shown by Chester et al in U.S.
Pat. No. 3,788,117. Since stretch forming often will severely distort the
honeycomb cells through compression on the concave side of the core,
Chester et al attempt to assure that the entire panel thickness is
stretched, avoiding compression of the inner surface. This method is not
capable of forming crowned curved surfaces and may cause severe distortion
if the panel does not slip uniformly on the forming surface. Panels having
a honeycomb core bonded to two face sheets have been formed into complex
curved shapes by hydraulic methods, such as described by Fuchs in U.S.
Pat. No. 3,373,460. This method can severely distort or crush the
honeycomb core, as seen in Fuchs, FIG. 3, and is not suitable for shaping
of honeycomb core sheets alone, since the face sheets are necessary to
provide a surface to react the hydraulic forces.
Thus, there is a continuing need for methods of forming metal honeycomb
sheets into simple and complex curved shapes without damage to the
honeycomb cells.
SUMMARY OF THE INVENTION
It is, therefore, an object of this invention to provide an apparatus and
method for expanding and contouring metal honeycomb sheets that overcome
the above-noted problems. Another object is to provide an apparatus and
method that can uniformly produce contoured honeycomb sheets without
damaging the fully formed honeycomb cells. A further object is to provide
an apparatus and method that is capable of producing a variety of high
quality crowned cylindrical honeycomb sheet shapes.
The above objects, and others, are accomplished in accordance with this
invention by an apparatus and method that initially expands a honeycomb
preform to a selected percentage of the final expansion, preferably from
about 50 to 80%, then gradually brings the preform into gradually
increasing sliding engagement with a crowned, freely rotatable, generally
cylindrical, surface during further expansion, typically 10 to 30% of full
expansion, and finally completes expansion, typically about 10-15% of full
expansion with the honeycomb in full contact with the forming surface to
set the final compound contour.
In some cases, a cylindrical, non-compound curved, expanded honeycomb sheet
is desired. If the preform is expanded around a simple cylindrical drum,
the product will be bowed slightly toward the inside of the cylinder. To
form a precise cylindrical expanded honeycomb product, the method and
apparatus of the invention are used with a suitably slightly crowned drum.
The basic apparatus includes a supporting structure on which a drum is
mounted for unrestricted, free, rotation. The surface of the drum is
crowned in a desired shape to provide a predetermined tool surface, which
is a surface of rotation, to produce the desired honeycomb sheet compound
contour. A fixed arm assembly includes a bar positioned adjacent to the
drum surface. A second arm assembly is mounted so as to pivot about the
drum axis with a second bar positioned adjacent to the drum surface. A
honeycomb preform is secured between the fixed and movable bars by
suitable connection means, such as wire loops, extending from each bar
around the adjacent edge strip of the preform.
In operation, the movable bar is moved away from the fixed bar to begin
expanding the honeycomb. Initially, the preform does not contact the drum
surface, so that the expanding honeycomb is initially essentially flat.
Eventually, at a selected point in the expansion, the expanding sheet
begins to contact the surface of the drum. Preferably, this contact begins
after the preform has expanded from about 50 to 80% of full expansion. The
honeycomb slides on the drum surface as further expansion brings more of
the honeycomb into contact with the drum surface during a further
expansion of about 10 to 30% of full expansion. The drum is completely
free to rotate in response to friction forces between expanding honeycomb
sheet and drum to accommodate expansion without "catching" cells on the
drum surface and distorting the cells in a sliding contact that may
involve a slight rotation of the drum. Finally, during the final expansion
of about 10-15% of the total expansion, the honeycomb sheet is in full
contact with the drum to set the final cell size and sheet compound
contour. The connections between the arm assemblies and the sheet are then
removed and the sheet is ready for further panel assembly processes.
During this expansion and forming operation it is desirable for the
honeycomb sheet to contact less than about 30% of the circumference of the
drum. Greater contact may undesirably over expand and deform the end
portions of the honeycomb sheet.
If desired, both of the arms could be pivoted about the drum axis and
movable away from each other, although the use of one fixed and one
movable arm is preferred for simplicity and effectiveness. A variety of
different connection means could be used between the arm assembly bars and
the preform, including wires, openable rings, clamps and the like.
The drum may have any suitable surface material. The surface material
coefficient of friction is selected to provide a suitable resistance to
sliding depending on the material from which the honeycomb is made. In
general, the lowest possible resistance to sliding is preferred. A hard
surface in relation to the hardness of the honeycomb core material is
preferred. The surface should be very smooth. Typical surface materials
include stainless steel cloth, fiberglass or graphite composite material,
steel, stainless steel and other hard materials with low friction surface
coatings. With aluminum honeycomb core, materials exhibiting smoothness,
high hardness relative to aluminum, low sliding friction and durability
are preferred.
BRIEF DESCRIPTION OF THE DRAWINGS
Details of the invention, and of certain preferred embodiments thereof,
will be further understood upon reference to the drawings, wherein:
FIG. 1 is a perspective view of the preferred apparatus of this invention
at the start of expansion;
FIG. 2 is a perspective view of the apparatus frame and drive system;
FIG. 3 is a partial perspective view of the apparatus with the honeycomb
core loaded, before expansion begins;
FIG. 4 is a perspective view of the apparatus of FIG. 3 during initial
expansion;
FIG. 5 is a perspective view of the apparatus of FIG. 3 at the completion
of expansion and forming;
FIG. 6 is a schematic elevation view showing the movable arm, drum and
frame attachment;
FIG. 7 is plan view of a honeycomb sheet made according to a prior art
method; and
FIG. 8 is a plan view of a honeycomb sheet made by the apparatus and method
of this invention.
DETAILED DESCRIPTION OF PREFERRED EMBODIMENT
Referring now to FIG. 1, there is seen a support structure or base 10. A
drum 12 is mounted for free, unrestricted, rotation on shaft 13 mounted in
bearings 14 mounted at the top of uprights 16 (as best seen in FIG. 6). In
FIG. 1, upright 16 on the near side is mostly enclosed within housing 18
that shrouds the arm drive system, as detailed below.
A fixed bar assembly 18 is mounted on support structure 10. The assembly 18
includes a pair of brackets 20 positioned near each end of drum 12 and
having a bar 22 running therebetween. Bar 22 is removably located in slots
23 in brackets 20.
A movable bar assembly 24 includes a pair of elongated arms 26 attached to
sprocket 27 mounted to shaft 13 at the ends of drum 12 and opening
allowing pivotably mounting on shaft 13. Drum 12 attaches to bearing 29 on
shaft 13 attached to bearings 14. The other ends of elongated arms 26 are
maintained in a spaced apart relationship by a spacer bar 28. Slots 30 at
the ends of arms 26 are adapted to support a removable bar 32. A
reversible drive system moves moveable arm assembly 24 between the
positions shown in FIGS. 3 through 5 under the control of a conventional
reversing switch 34.
A suitable honeycomb preform 36 is positioned between fixed bar 22 and
movable bar 32. A plurality of wires 38 are threaded through preform
strips near the edges of preform 36, around bars 22 or 32, respectively
and tied or twisted, as shown. Any other suitable connecting or clamping
devices may be used, if desired to flexibly secure the preform edges to
the fixed and movable bars 22 and 32 As seen in FIG. 1, the apparatus is
ready to begin the honeycomb and expansion and forming operation.
FIG. 2 shows the apparatus of FIG. 1 from a slightly different point of
view, with the drum 12 removed. As seen in FIGS. 3 and 4, bars 22 and 32
are spaced from the surface of drum 12, as bar 32 is pivoted around drum
12 to initially preform the honeycomb core 36 and to expand it into a flat
partially expanded honeycomb sheet as seen in FIG. 4. This initial
expansion is preferably about 50 to 80% of full expansion. Eventually,
depending on the position selected for fixed bar 22 on brackets 20 and the
length of arms 26 and the position selected for arm 32 relative to the
surface of drum 12, the partially expanded preform 36 will come into
contact with the top of the crowned drum surface.
Thereafter, the preform 36 will engage the drum surface, possibly rotating
the drum as it slides over the drum surface. I have found that this
combined rotation and sliding action avoids deformation of the expanding
honeycomb cells. During this second step, further expansion of the
honeycomb core takes place, preferably from about 10 to 30%, as well as
initial forming over step it is desirable for the honeycomb sheet to
contact less than about 30% of the circumference of the drum. Greater
contact may undesirably over expand and deform the end portions of the
honeycomb sheet.
Eventually, the expanding preform reaches full expansion, as shown in FIG.
5 to fully expand the core and to "set" the final deformation downwardly
over the crowned drum 12. the expanded preform 36 is in full contact with
the crowned drum surface. Wires 38 can then be removed and the expanded,
shaped, honeycomb sheet can be removed. The edges of the sheet are trimmed
to the desired dimensions and the sheet is ready for further processing,
such as bonding face sheets thereto. Switch 34 is then activated to
reverse the drive system to return the movable arm assembly 24 to the
position shown in FIGS. 1 and 3.
A conventional reversible electric motor 40 is mounted on support structure
10. Sprockets 42 and 27 are drivingly connected to motor 40 and one of
arms 26, respectively. Drive chain 46 runs between sprockets 42 and 27.
Sprocket 27 is secured to an arm 26, such as by bolts or rivets. Drum 12
rotates freely about the shaft while the shaft 13, arms 26 and sprockets
27 are fixed to each other and rotate as a unit. Switch 34 (FIGS. 1 and 2)
is a conventional reversing switch which selectively causes motor 40 to
operate in either direction. Conventional limit switches can be mounted on
support structure 10, if desired, to limit movement of arms to travel
between the positions of FIGS. 3 and 5.
Examples of typical honeycomb cell structure produced by the forming
methods of the prior art and by the method and apparatus of this invention
are provided in FIGS. 7 and 8, which are drawings based on photographs of
actual honeycomb sheets. As seen in FIG. 7, the prior art roll forming
method described above tends to distort the cell pattern of honeycomb 50,
showing a number of damaged cells 52. Further, although not readily
apparent in this view, the wall edges of the cells are often damaged, so
that the cell walls will not meet and bond well to a face sheet which is
later applied to the face of the honeycomb core sheet. As seen in FIG. 8,
uniform, regular hexagonal honeycomb cells 54 result when the expanded
honeycomb sheet is prepared in accordance with this invention.
While certain specific relationships, arrangements and materials were
specified in the above description of preferred embodiments, those may be
varied, where suitable, with similar results. For example, honeycomb
preforms made from a variety of materials may be formed using this method
and apparatus, and various coatings, lubricants, etc. could be used on the
crowned drum surface to optimize the surface coefficient of friction for
specific honeycomb sizes and materials.
Other applications, variations and ramifications of this invention will
occur to those skilled in the art upon reading this disclosure. For
example, certain arm and bar assemblies may be made to accommodate various
application requirements. Those are intended to be included within the
scope of this invention, as defined in the appended claims.
Top